Highlights from the American Journal of Pathology

Share

Tenascin-C affects proto-oncogene function in breast cancer, a group led by Dr. Peter Lloyd Jones at the University of Dundee, Dundee, Scotland; the University of Colorado Denver, Aurora, CO; and the University of Pennsylvania, Philadelphia, PA has demonstrated. Their report can be found in the February 2010 issue of The American Journal of Pathology.

Advertisement

Breast cancer causes over half a million deaths annually worldwide. Much research has focused on the role of cancer-causing oncogenes and their precursors, non-carcinogenic proto-oncogenes, within the breast epithelium, the tissue from which most breast cancers are derived. The role of the surrounding cells, or stroma, and the molecules they secrete, such as the extracellular matrix, on transformation of proto-oncogenes to oncogenes in breast cancer remains relatively unexplored.

Advertisement

To determine how stromal extracellular matrix remodeling affects proto-oncogene expression in breast epithelia, Taraseviciute et al developed a computational model to quantify changes in a 3-D culture of human mammary epithelial cells. They found that tenascin-C, a stromal glycoprotein whose expression correlates with disease severity, promoted cancer-like properties, similar to the results of overexpression of the oncogene c-met. Indeed, tenascin-C increased c-met expression, and tenascin-C-induced carcinogenesis was inhibited by blocking c-met function. Taken together, these results indicate a role for stromal changes in regulating proto-oncogene function.

Dr. Jones and colleagues suggest "that micro-environmental cues originating within the tumor stroma can act in both a dominant and paracrine fashion to control the expression and function of epithelial genes already associated with the development and progression of breast cancer."

Dr. Kenji Kabashima and colleagues at the Kyoto University Graduate School of Medicine have discovered that Wnt signaling is involved in the development of pachydermoperiostosis. They present these findings in the February 2010 issue of The American Journal of Pathology.

Pachydermoperiostosis is a rare skin disease characterized by pachydermia (skin thickening), digital clubbing, and periostosis (abnormal bone deposits) of long bones. Fibroblasts help to form the structural framework for various tissues, including the skin and bones, and therefore likely play a role in this process. As the Wnt signaling pathway plays a developmental role in both bone and skin, Kabashima et al hypothesized that Wnt signaling was involved in the development of pachydermia. They found that DKK1, a Wnt-signaling antagonist, was expressed at lower levels in pachydermoperiostosis than in control fibroblasts, whereas the Wnt-signaling molecule β-catenin was expressed at higher levels. In addition, expression of DKK1 inhibited fibroblast proliferation, and DKK1-inhibition increased skin thickening in mouse ears. Therefore, enhanced Wnt signaling may contribute to pachydermia by increasing levels of fibroblast proliferation.

Dr. Kabashima and colleagues therefore conclude that "enhanced Wnt signaling is related to the development of pachydermia."

Researchers led by Dr. Sabita Roy at the University of Minnesota have found that chronic morphine use delays wound healing in the presence on an infection. They report their data in the February 2010 issue of The American Journal of Pathology.

Morphine acts on cells in the central nervous system, resulting in pain relief and analgesia; however, morphine use may also affect the immune system. Indeed, chronic morphine users and opioid abusers have inadequate wound closure and increased susceptibility to infection.

To further address this issue, Martin et al examined wound healing in a mouse model of chronic morphine use/abuse. In the presence of inflammation, chronic morphine exposure resulted in a marked decrease in wound closure, compromised wound integrity, and increased bacterial sepsis. With morphine exposure, expression of particular immune molecules was altered, which led to decreased recruitment of immune cells to the wound site. New blood vessel formation and recruitment of replacement cells were also suppressed in these animals. These data suggest that the immunosuppression due to morphine treatment delays immune cell recruitment, leading to lack of bacterial clearance and delayed wound closure.

Dr. Roy's group concludes that "these studies provide an in vivo tool by which further mechanistic experiments can be performed to address why, clinically, heroin-addicted patients often present with infected non-healing wounds. Understanding these underlying mechanisms affords improved treatment options not only for chronic morphine users and abusers, but can also have translational implications for immuno-compromised populations such as the elderly or those who are chronically stressed."

A group led by Dr. Peter C. Butler of the University of California, Los Angeles, CA has discovered that small clusters (oligomers) of islet amyloid polypeptides (IAPPs) may contribute to the onset of type 2 diabetes mellitus. These results are presented in the February 2010 issue of The American Journal of Pathology.

Type 2 diabetes, or non-insulin-dependent diabetes, is characterized by high blood glucose in the presence of insulin resistance. Rates of diabetes doubled in the United States between 1990 and 2005, with nearly 23.6 million people diagnosed with diabetes.

In patients with type 2 diabetes, beta cells, the cells in the pancreas that secrete insulin, are progressively lost, and this loss is often associated with the accumulation of misfolded proteins, in particular IAPP. Similar amyloid protein accumulation has been implicated in the pathogenesis of diverse neurodegenerative diseases including Alzheimer, Parkinson's, and Huntington's disease. Gurlo et al explored the role of IAPP amyloids in type 2 diabetes pathology. They discovered that small clusters (oligomers) of IAPP formed within the beta cells and disrupted the membranes required for insulin secretion. These oligomers were also found in beta cells in human patients with type 2 diabetes. Moreover, IAPP oligomers also disrupted mitochondrial membranes, which can result in beta cell death.

Gurlo et al suggest that "IAPP toxic oligomers form within the secretory pathway in beta cells, to an increased extent in [type 2 diabetes] and as a function of obesity. ... Taking the present study along with the known properties of toxic IAPP oligomers to induce membrane damage, we conclude that toxic oligomers may contribute to the beta cell dysfunction and apoptosis characteristic of type 2 diabetes."

Researchers at the University of Pittsburgh, Pittsburgh, PA have demonstrated that the Wnt/β-catenin signaling pathway plays a key role in hepatic bile acid and cholesterol homeostasis as well as helps protect the adult liver against metabolic stress. Their report can be found in the February 2010 issue of The American Journal of Pathology.

The liver has a wide range of functions, including detoxification, protein synthesis, and production of biochemicals necessary for digestion. The liver is the primary organ involved in lipid metabolism, and liver dysfunction often results in accumulation of lipids within the liver (steatosis). The Wnt/β-catenin signaling pathway is involved in liver development, regeneration, and liver cancer; however, its role in non-cancerous liver disease has not been well characterized.

To determine the effects of β-catenin-deficiency on lipid accumulation and injury in the liver, Behari et al induced dietary-caused liver injury in both wild-type and β-catenin-deficient mice. They found that β-catenin-deficient mice developed higher levels of lipid accumulation and fibrosis as well as accumulated higher liver cholesterol levels than wild-type mice. Furthermore, β-catenin-deficient mice had higher levels of bile acid, which aid in digestion of dietary fat, despite lower expression of bile acid synthesis enzymes, suggesting defects in bile transport. These findings suggest that β-catenin signaling plays a key role in hepatic bile acid and cholesterol homeostasis as well as in protecting against metabolic stress.

The findings by Behari and colleagues "suggest that β-catenin is an additional player in the complex network of nuclear receptors that regulates bile acid and lipid metabolism in the liver. Identifying the interactions between these receptors and β-catenin may help elucidate additional regulatory mechanisms that could have potential therapeutic implications in both cholestatic and metabolic liver diseases."

Your comments are automatically posted once they are submitted. All comments are however constantly reviewed for spam and irrelevant material (such as product or personal advertisements, email addresses, telephone numbers and website address). Such insertions do not conform to our policy and 'Terms of Use' and are either deleted or edited and republished.Please keep your comments brief and relevant.This section may also have questions seeking help. If you have the information you are welcome to respond, but please ensure that the information so provided is genuine and not misleading.

Disclaimer - All information and content on this site are for information and educational purposes only. The information should not be used for either diagnosis or treatment or both for any health related problem or disease. Always seek the advice of a qualified physician for medical diagnosis and treatment.Full Disclaimer